Multichannel Preparative Electrophoresis System

ABSTRACT

The invention provides an electrophoresis cassette, methods for making the electrophoresis cassette, and method of fractionating analytes from a sample based upon electrophoretic mobility in a single application of the sample to an electrophoretic system.

RELATED APPLICATIONS

This application is a continuation of U.S. patent application U.S. Ser. No. 12/760,548, filed Apr. 14, 2010 (now U.S. Pat. No. 8,361,299), which is a continuation-in-part of U.S. Ser. No. 12/576,148 (now U.S. Pat. No. 8,361,298), filed on Oct. 8, 2009, which claims priority to provisional application U.S. Ser. No. 61/195,566, filed Oct. 8, 2008, and to provisional application U.S. Ser. No. 61/150,243, filed Feb. 5, 2009, the contents of which are each herein incorporated by reference in their entirety.

FIELD OF THE INVENTION

This invention relates generally to the field of molecular biology. Systems and methods of the invention are used to prepare and analyze DNA, RNA, and proteins from biological samples.

BACKGROUND OF THE INVENTION

Electrophoretic separation of DNA fragments is used for a number of purposes in molecular and clinical biology and medicine, including next generation DNA sequencing, medical diagnostics, forensic science and DNA computing.

Preparative gel electrophoresis of DNA has good resolution, adequate capacity and ease of use on a small scale. However, the manual process is both time and labor intensive. Critically, it is difficult to remove the desired DNA fraction from the gel. This removal process routinely entails excising a band or portion from the gel containing the DNA of interest and then extracting it by a variety of chemical and physical means including the use of enzymes, centrifugation, freezing and more. Importantly, these methods substantially reduce the amount of DNA harvested and dilute the resultant DNA into large volumes of fluid, therefore, requiring additional time and expense to re-concentrate it into a smaller, usable, aliquot. This problem is so significant to the field of molecular biology, in fact, that the removal of DNA from gels in small volumes of fluid has spawned a separate industry for making various types of kits, reagents and devices to accomplish the task. However, despite a demonstrated need and the efforts of skilled artisans, a solution has not yet been developed.

SUMMARY OF THE INVENTION

The invention provides compositions including electrophorsis cassettes and preparative electrophoresis systems as well as methods of fractionating analytes from a sample. Electrophoresis cassettes and preparative electrophoresis systems of the invention fractionate nucleic acids or polypeptides of a specified or desired molecular weight or electrophoretic mobility from a biological sample, and subsequently extract the desired nucleic acids or polypeptides from the gel matrix or buffer compositions by drawing them across an analyte and ion permeable barrier and into an elution chamber.

Specifically, the invention provides an electrophoresis cassette containing a plate including at least one macrofluidic separation channel, the channel having a first physically and electrically isolated portion and a second physically and electrically isolated portion; and an elution chamber positioned on one or another of the physically and electrically isolated portions, the chamber comprising at least one an elution cavity and an analyte-impermeable barrier. The elution chamber is attached or removable. For instance, the elution chamber is generated by inserting an elution chamber insert into an elution chamber cavity within the first or second physically and electrically separated portion of the separation channel, inserting a liquid gel matrix composition into the separation channel, solidifying the gel matrix composition, removing the elution chamber insert thereby generating an elution chamber, placing an analyte-impermeable barrier on the distal side of the elution chamber, and filling the elution chamber with an elution buffer composition. The term “solidifying” is meant to describe a process by which either a liquid matrix organizes into a solid gel form (which may be temperature-dependent), or alternatively, a process by which liquid matrix components polymerize to form a solid gel. Regardless of the gel matrix composition used, the composition is injected as a liquid, and subsequently transforms into a solid once inside the cassette.

Alternatively, or in addition, an elution chamber of the above electrophoresis cassette further include at least one of an analyte-permeable barrier, a sample collection chamber including a sample removal port, and an analyte-impermeable barrier.

Furthermore, the elution chamber is removable. In certain embodiments of the elution chamber, the chamber contains, in the direction of electrophoresis, a first removable side, an analyte-permeable membrane, a sample collection chamber, an analyte-impermeable membrane, and a second removable side. The removable sides are removable portions of the sample collection chamber with at least one of an opening, protrusion, or recession for binding either the analyte-permeable or analyte-impermeable membrane to the sample collection chamber. Alternatively, the removable sides are O-rings that fit within a first and second side of the sample collection chamber and bind either the analyte-permeable or analyte-impermeable membrane to the sample collection chamber. A removable elution chamber is also used as an elution chamber insert, as described above. The removable elution chamber is attached to the elution chamber cavity within the first or second physically and electrically isolated portion of the separation channel.

The analyte-permeable barrier of the elution chamber is a hydrophilic membrane or filter. In certain embodiments, the analyte-permeable barrier includes a least one pore having a diameter range of between 0.4 micron to 50 microns, and preferably, of between 0.4 micron to 1 micron.

The analyte-impermeable barrier of the elution chamber is a membrane, filter, film, or any combination thereof. Preferably, the analyte-impermeable barrier is an ultrafiltration membrane or a conductive film. In certain embodiments, the ultrafiltration membrane contains a least one pore having a diameter range of between 0.001 micron to 0.1 micron. Alternatively, or in addition, the ultrafiltration membrane has a molecular weight cutoff of between 1,000 to 30,000 daltons. Preferably, the ultrafiltration membrane has a molecular weight cutoff of between 3,000 to 10,000 daltons. In other embodiments, the analyte-impermeable barrier includes a conductive film having the same charge as the analyte or a conductive film contacted with negatively-charged sulfate groups. In certain aspects, the analyte-impermeable barrier is Nafion.

The electrophoresis cassette also includes a constriction point provided between the separation channel and at least one of the first and second physically and electrically isolated portions.

In certain embodiments of the cassette, at least one macrofluidic separation channel is tapered from one end to the constriction point. Alternatively, or in addition, at least one macrofluidic separation channel is optically-transparent. In other embodiments, the separation channel is optically-transparent on at least one side, on only one side, or on only a portion of one side. For instance, the separation channel is optically-transparent on the bottom side, the top side, or both bottom and top sides. Preferably, optical transparency is maintained along the separation channel from the distal edge of the sample well cavity to the division point.

The electrophoresis cassette contains at least one dam within at least one separation channel. Preferably, the electrophoresis cassette contains two dams within at least one separation channel. The term “dam” is meant to describe a barrier structure that partitions the separation channel. In one embodiment of the invention, a dam is positioned in at least one separation channel distal to the buffer reservoir and proximal to the sample well cavity. In another embodiment, a dam is positioned in at least one separation channel distal to a division point and proximal to a waste reservoir. The dam is formed from a frame onto which is attached to an ion-permeable barrier. The ion-permeable barrier is also preferably permeable to the buffer composition. The frame recapitulates the geometry of the separation channel, i.e. if the channel is rectangular, then the dam frame is rectangular. The ion-permeable barrier is composed of a hydrophilic membrane or filter. In certain embodiments, the hydrophilic membrane or filter includes a least one pore having a diameter range of between 0.001 micron to 1 micron, and preferably, of between 0.45 micron to 1 micron. The analyte permeable or impermeable membranes described herein for use in the elution chamber could also be used as a membrane for a dam. Importantly, the dam structure restrains the flow of unsolidified gel matrix molecules to the separation channel during gel casting, e.g. the portion of the separation channel between the first dam and the second dam. The dam is electrically conductive, and therefore, does not disrupt or distort electric fields or currents present in or around the at least one separation channel. Preferably, dam structures are inserted prior to attachment of the cover, and, therefore, in these preferred embodiments, the dam structures are permanent. Alternatively, the dam is removable from at least one separation channel because the cover is not permanently attached onto the base of the electrophoresis cassette. The dam occupies the total cross-sectional area of the separation channel. Accordingly, a dam prevents gel matrix molecules from traversing is membrane, that upon injection of a gel-matrix composition, effectively partitions the separation channel into at least one buffer- and at least one gel matrix-filled compartment, respectively.

The electrophoresis cassette contains between 1 and 5 macrofluidic separation channels. Alternatively, the cassette contains between 1 and 9 or between 1 and 13 macrofluidic separation channels. The maximum number of macrofluidic separation channels contained in the electrophoresis cassette is determined by the ability of a detection system to read the cassette, and in theory, no maximum number exists, however, a practical range of is between 25-33 macrofluidic channels.

The electrophoresis cassette also contains a buffer reservoir for each of the macrofluidic separation channels.

The electrophoresis cassette includes a cover for the plate. In one aspect, the cover includes a configuration that corresponds to the configuration of the top of the plate. In another aspect, the cover includes at least one of an opening, a protrusion and a recess that align with at least one of the buffer reservoirs. Alternatively, or in addition, the cover includes at least one of an opening, a protrusion and a recess that align with at least one of the macrofluidic channel, the buffer reservoir, the sample well cavity, the sample removal port, the elution reservoir, the waste reservoir, and the first and second physically and electrically isolated portions. In another embodiment, the cover includes at least one of an opening, a protrusion and a recess that align with at least one of the macrofluidic channel, the sample well cavity, and the sample removal port. The cover may further include at least one of an electrode port, a vent, and a sample well port. The electrode port is either negative or positive. In a preferred embodiment, the at least one negative electrode port is positioned proximal to the sample well cavity. In another preferred embodiment, the at least one positive electrode port is positioned distal to either the elution chamber or the cavity for the second dam.

Moreover, the electrophoresis cassette contains at least one of a cavity for a first dam, sample well cavity, an elution reservoir, a cavity for a second dam, and a waste reservoir. In certain embodiments of the invention, the elution reservoir and the waste reservoir are provided at an end of the first physically and electrically isolated portions and the second physically and electrically isolated portions, respectively.

The electrophoresis cassette further includes a division point provided between the macrofluidic channel and the elution reservoir and the waste reservoir. In certain embodiments of the cassette, the constriction point is the division point.

The macrofluidic channel of the electrophoresis cassette includes at least one of a gel matrix composition, a liquid buffer composition, a solid buffer composition. In aspects, at least one of a gel matrix composition, a liquid buffer composition, a solid buffer composition contains at least one of a fluorophore or a chromophore. The fluorophore is either the analyte or is bound to the analyte. Similarly, the chromophore is either the analyte or is bound to the analyte. An exemplary fluorophore is ethidium bromide, which binds to polynucleic acids and allows detection of the polynucleic acid analyte. Moreover, a polypeptide analyte is a chromophore because it can be detected by mere absorption of ultraviolet light.

At least one macrofluidic separation channel of the electrophoresis cassette contains a gel matrix composition. In one aspect, the gel matrix composition fills a volume of the macrofluidic separation channel, including at least one of the first and second physically and electrically isolated portions. In another aspect, the gel matrix composition defines at least one sample well within at least one sample well cavity.

Sample wells have multiple geometries. The geometry of the sample well reflects the geometry of the sample well insert used to define the negative space not occupied by the gel matrix composition. In certain aspects of the invention, a sample well insert is used in combination with a stripper plate to create a terraced geometry, the negative space of which will form the sample well. Critically, the sample wells of the invention have the have a unique and essential “chimney” shape, forming a “gel chimney,” in which the walls of the sample well extend through the sample well insert opening and into the sample well port, as depicted in FIGS. 44-48. The cover plate is specifically adapted with walls surrounding the sample well insert opening to support the sides of this chimney-shaped sample well. The chimney-shaped sample well prevents entry of the sample into the seam between the upper surface of the gel and the bottom surface of the cassette cover plate. Such entry can occur by capillary flow, or by electrophoresis. Sample molecules entering the seam travel at a different rate than that of sample molecules traveling through the gel. For this reason, undesired sample molecules traveling in the seam may be drawn into the elution chamber during elution, thereby contaminating the desired sample components that have been traveling through the gel. The contamination typically travels unpredictably, but often faster than the material traveling through the gel in the separation channel, causing inappropriately large molecules to enter the elution chamber.

The macrofluidic separation channel further contains a lens positioned between the sample well cavity and the division point. The lens includes a gel matrix composition. In certain embodiments, the gel matrix composition of the lens contains a higher concentration of a polymer, thereby making the lens denser. The lens takes any shape, including a curve that follows the direction of electrophoresis. Functionally, the lens focuses at least one of an analyte. The lens is positioned proximal or distal to a constriction point or to a detection zone within the separation channel.

Furthermore, at least one macrofluidic channel of the electrophoresis cassette contains a buffer composition. In one aspect, the buffer composition fills a volume of at least one buffer reservoir, at least one sample well, at least one elution reservoir, and at least one waste reservoir.

At least one elution chamber of the electrophoresis cassette contains an elution buffer composition. In one aspect, the elution buffer composition fills a volume of at least one elution chamber.

The electrophoresis cassette of the invention is meant to be compatible with a variety of detection systems. As such, certain embodiments of the cassette contain an integrated electrode array. In this aspect, the cassette contains: a negative electrode positioned between the buffer reservoir and a corresponding end of the separation channel; a positive electrode positioned between an end of the first physically and electrically isolated portion and the elution reservoir; and a positive electrode positioned between an end of the second physically and electrically isolated portion and the waste reservoir.

The electrophoresis cassette further includes a removable seal. Non-limiting examples of seal materials are polymers, adhesive films, and tapes. The seal encloses at least one of an opening, a protrusion and a recess of the cover. Alternatively, or in addition, the seal encloses the entirety of the electrophoresis cassette. Functionally, the seal prevents spillage and evaporation of the buffer and gel matrix compositions contained within the cassette during storage. Moreover, the seal prevents the buffer and gel matrix compositions contained within the cassette from contacting or corroding the electrode array during storage.

Regardless of the features present within the electrophoresis cassette, the cassette is disposable.

The invention also provides a method of making an electrophoresis cassette, including: providing the above electrophoresis cassette, wherein the cassette further contains at least one of a buffer reservoir insert, a sample well insert, a waste reservoir insert, and a cover, wherein the buffer reservoir insert includes a vent, wherein the buffer reservoir insert traverses an opening in the cover plate aligned with the buffer reservoir, wherein the sample well insert traverses an opening in the cover plate aligned with the sample well cavity, wherein the waste reservoir insert includes an injection port, and wherein the waste reservoir insert traverses an opening in the cover plate aligned with the waste reservoir; inserting a gel matrix composition through the injection port; solidifying the gel matrix composition, wherein the gel matrix composition transforms from a liquid to a solid; removing the buffer reservoir insert, sample well insert, and waste reservoir insert, wherein a buffer reservoir, a sample well, an elution reservoir, and a waste reservoir are generated; filling the buffer reservoir, the elution reservoir, and the waste reservoir with a buffer composition; filling the elution chamber with an elution buffer composition; and sealing the electrophoresis cassette.

In other embodiments, the method includes providing the above electrophoresis cassette, wherein the cassette further contains at least one of a sample well insert and a cover, wherein the sample well insert traverses an opening in the cover plate aligned with the sample well cavity; inserting a gel matrix composition through the injection port; solidifying the gel matrix composition, wherein the gel matrix composition transforms from a liquid to a solid; removing the sample well insert, wherein a sample well is generated; filling the buffer reservoir, the elution reservoir, and the waste reservoir with a buffer composition; filling the elution chamber with an elution buffer composition; and sealing the electrophoresis cassette. In this embodiment, the gel is cast in the electrophoresis cassette, without the use of a casting fixture, and the cassette is oriented or placed horizontally during the inserting and solidifying steps.

In one aspect the above method further includes the steps of: providing a casting fixture, wherein the fixture includes a front plate that contacts the top of the cassette, wherein the front plate contains at least one opening that aligns with at least one of the vent of the buffer reservoir insert and the separation channel, and a back plate that contacts the bottom of the cassette, wherein the back plate contains at least one opening; attaching the casting fixture to electrophoresis cassette, wherein the back plate contacts the bottom of the electrophoresis cassette and the front plate contacts the top of the electrophoresis cassette, and wherein the back and front plates are attached to each other; wherein the casting fixture is provided and attached prior to the injecting step and, detaching the casting fixture from the electrophoresis cassette prior to the removing step.

According to this method, the buffer reservoir insert fills a volume of the buffer reservoir. Moreover, the sample well insert fills a volume of the sample well cavity. Furthermore, the waste reservoir insert fills a volume of the waste reservoir.

In one aspect of this method the electrophoresis cassette or casting fixture is horizontal or vertical during the inserting and solidifying steps.

The cassette provided for this method contains between 1 and 5 macrofluidic separation channels. Alternatively, the cassette contains between 1 and 9 or between 1 and 13 macrofluidic separation channels.

The invention also provides a detection system for detecting a property of an analyte within a sample including: the above-described electrophoresis cassette; an electrode array comprising at least one of a negative electrode and a positive electrode, wherein the negative electrode aligns with a position on the cassette between the buffer reservoir and a corresponding end of the separation channel, and wherein the positive electrode aligns with a physically and electrically isolated portion of the separation channel; a detector positioned near the separation channel of the electrophoresis cassette, wherein the detector detects a property of an analyte; a processor configured to activate or deactivate power to at least one positive electrode based upon a signal received from the detector; and a power module comprising at least one of a power supply and a relay to provide power to at least one of the processor, the negative electrode and at least one positive electrode.

In certain embodiments of this system, the detected property is an optical property of an analyte. Exemplary optical properties include, but are not limited to, the emission or absorption of light. Furthermore, the detected property includes magnetism, radiation, temperature, color, energy, or changes in any of the above.

The sample of this system contains a detectable label, such as a magnetic, paramagnetic, radioactive, enzymatic, immunological, or optical label. Non-limiting examples of optical labels are fluorescent and light-absorbing compounds. In one aspect, the sample contains a fluorescent compound and the analyte forms a complex with the fluorescent compound. In another aspect, the fluorescent compound or the analyte is a fluorophore. In another embodiment, the sample comprises a light-absorbing compound and the analyte forms a complex with the light-absorbing compound. Alternatively, the light-absorbing compound or the analyte is a chromophore.

The analyte of this system is a sample or a molecular weight marker.

In a preferred embodiment of this system, the detector detects a property of the molecular weight marker within a first macrofluidic channel and sends a signal to the processor. Subsequently, the processor receives the signal from the detector and applies an algorithm to determine the molecular weight of at least one of an analyte at the division point of a second macrofluidic channel.

The invention provides a method of fractionating analytes within a sample, including: providing an electrophoresis cassette described herein, wherein the cassette further comprises at least one of a buffer reservoir insert, a sample well insert, and a waste reservoir insert, and a cover, wherein the buffer reservoir insert includes a vent, wherein the buffer reservoir insert traverses an opening in the cover plate aligned with the buffer reservoir, wherein the sample well insert traverses an opening in the cover plate aligned with the sample well cavity, wherein the waste reservoir insert includes an injection port, and wherein the waste reservoir insert traverses an opening in the cover plate aligned with the waste reservoir; inserting a gel matrix composition through the injection port; solidifying the gel matrix composition, wherein the gel matrix composition transforms from a liquid to a solid; removing the buffer reservoir insert, sample well insert, and waste reservoir insert, wherein a buffer reservoir, a sample well, an elution reservoir, and a waste reservoir are generated; filling the buffer reservoir, an elution reservoir, and a waste reservoir with a buffer composition; filling the elution chamber with an elution buffer composition; and inserting the electrophoresis cassette into a detection system described herein; programming the processor of the detection system to selectively activate the positive electrode of the electrode array aligned with the physically and electrically isolated portion of the separation channel comprising the elution chamber when the processor determines that at least one of an analyte of the desired molecular weight is traversing the division point of the separation channel; applying the sample to the sample well; applying a voltage across the electrophoresis cassette; collecting analytes of the sample having a desired electrophoretic mobility in the elution chamber, thereby fractionating analytes within a sample. In certain embodiments, this method includes providing an electrophoresis cassette described herein, wherein the cassette further comprises at least one of a sample well insert and a cover, wherein the sample well insert traverses an opening in the cover plate aligned with the sample well cavity; inserting a gel matrix composition through the injection port; solidifying the gel matrix composition, wherein the gel matrix composition transforms from a liquid to a solid; removing the sample well insert, wherein a sample well is generated; filling the buffer reservoir, an elution reservoir, and a waste reservoir with a buffer composition; filling the elution chamber with an elution buffer composition; and inserting the electrophoresis cassette into a detection system described herein. In this embodiment, the gel is cast in the electrophoresis cassette, without the use of a casting fixture, and the cassette is oriented or placed horizontally during the inserting and solidifying steps.

This method further includes the steps of: providing a casting fixture, wherein the fixture includes a front plate that contacts the top of the cassette, wherein the front plate comprises at least one opening that aligns with at least one of the vent of the buffer reservoir insert and the separation channel, and a back plate that contacts the bottom of the cassette, wherein the back plate comprises at least one opening; attaching the casting fixture to electrophoresis cassette, wherein the back plate contacts the bottom of the electrophoresis cassette and the front plate contacts the top of the electrophoresis cassette, and wherein the back and front plates are attached to each other; wherein the casting fixture is provided and attached prior to the injecting step and, detaching the casting fixture from the electrophoresis cassette prior to the removing step.

In one aspect of this method, the sample contains a molecular weight marker. In another aspect of this method, the analyte is a polynucleic acid or a polypeptide. Moreover, the polynucleic acid contains deoxyribonucleic acid (DNA) or ribonucleic acid (RNA). Alternatively, or in addition, the polynucleic acid is double or single stranded. In certain aspects, the polypeptide is native or denatured.

In one aspect of this method, the sample contains at detectable compound. Exemplary detectable compounds are magnetically-, paramagnetically-, radioactively-, enzymatically-, immunologically-, or optically-detectable. Optically-detectable compounds are, for example, fluorescent and light-absorbing compounds. In certain embodiments, the sample contains at least one of a complex of an analyte and a fluorescent compound. In one aspect, the fluorescent compound is a fluorophore. In another aspect, the analyte is a fluorescent compound or fluorophore. Alternatively, or in addition, the sample contains at least one of a complex of an analyte and a light-absorbing compound. In one embodiment, the light-absorbing compound is a chromophore. In another embodiment, the analyte is a light-absorbing compound or chromophore.

According to this method, at least one of the gel matrix composition, the buffer composition, or the elution buffer composition comprises at least one of a fluorophore that complexes to at least one of an analyte. Moreover, at least one of the gel matrix composition, the buffer composition, or the elution buffer composition comprises at least one of a chromophore that complexes to at least one of an analyte.

According to this method, the processor of the detection system selectively activates the positive electrode of the electrode array aligned with the physically and electrically isolated portion of the separation channel comprising the elution chamber when an analyte having a specified electrophoretic mobility is detected and wherein the specified electrophoretic mobility is distinct for each macrofluidic channel.

The invention provides a composition containing an electrophoresis cassette, the electrophoresis cassette including: (a) a channel plate including a macrofluidic channel, wherein the macrofluidic channel comprises, from proximal to distal, a buffer reservoir, a first end of a separation channel, a sample well cavity, a constriction point, a division point, an elution chamber cavity, a second physically and electrically isolated end of the separation channel, a third physically and electrically isolated end of the separation channel, an elution reservoir, and a waste reservoir; (b) an elution chamber including, from proximal to distal, an analyte-permeable barrier, a sample collection chamber having a sample removal port, and an analyte-impermeable barrier, wherein the elution module is attached to the elution chamber cavity; (c) a cover plate that contacts the top of the channel plate, wherein the cover plate contains at least one of an opening, a protrusion, and a recess that align, from proximal to distal, with the buffer reservoir, the sample well cavity, the elution chamber, a combination of the second physically and electrically isolated end of the separation channel and the elution reservoir, and a combination of the third physically and electrically isolated end of the separation channel, and the waste reservoir; (d) a gel matrix composition that fills the macrofluidic separation channel and defines a sample well within the sample well cavity; (e) a liquid buffer composition that fills the buffer reservoir, the sample well, the elution reservoir, and the waste reservoir; (0 an elution buffer composition that fills the elution chamber; and (g) a seal that encloses the electrophoresis cassette.

In other embodiments of this composition, the electrophoresis cassette includes, (a) a channel plate including a macrofluidic channel, wherein the macrofluidic channel comprises, from proximal to distal, a buffer reservoir, a first end of a separation channel, a cavity for a first dam, a sample well cavity, a constriction point, a division point, an elution chamber cavity, a second physically and electrically isolated end of the separation channel, a third physically and electrically isolated end of the separation channel, an elution reservoir, a cavity for a second dam, and a waste reservoir; (b) an elution chamber including, from proximal to distal, an analyte-permeable barrier, a sample collection chamber having a sample removal port, and an analyte-impermeable barrier, wherein the elution module is attached to the elution chamber cavity; (c) a cover plate that contacts the top of the channel plate, wherein the cover plate contains at least one of an opening, a protrusion, and a recess that align, from proximal to distal, with the sample well cavity and the elution chamber; (d) a gel matrix composition that fills the macrofluidic separation channel and defines a sample well within the sample well cavity; (e) a liquid buffer composition that fills the buffer reservoir, the sample well, the elution reservoir, and the waste reservoir; (f) an elution buffer composition that fills the elution chamber; and (g) a seal that encloses the electrophoresis cassette. In certain aspects, the cover further includes at least one of an electrode port, a vent, a sample well port, and an injection port. The electrode port is either negative or positive. In a preferred embodiment, the at least one negative electrode port is positioned proximal to the sample well cavity. In another preferred embodiment, the at least one positive electrode port is positioned distal to either the elution chamber or the cavity for the second dam. In other aspects of the composition, at least one of the cavity for the first dam and the cavity for the second dam contain a first dam or a second dam, respectively. Alternatively, or in addition, the composition contains a sample well that forms a gel chimney.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is an illustration of the electrophoresis cassette used for Example 1.

FIG. 1B is the illustration of FIG. 1, shown from an alternate perspective.

FIG. 1C is an illustration of an electrophoresis cassette providing dimensions of separation channel. Inserts are shown as transparent outlines. In an exemplary embodiment, the length from the distal edge of the sample well to the division point is approximately 53 mm.

FIG. 1D is a schematic representation of the front view of channel plate at the division point of the separation channel. Length of “a” is, for example, 1.75 mm.

FIG. 2A-L is a series of photographs showing the fractionation of genomic DNA by size differentiation over time using the electrophoresis cassette of FIG. 1 and Example 1. The arrow indicates the direction of electrophoresis at the division point, i.e. the arrow points in the direction of the positive electrode that is differentially activated.

FIG. 2M is a photograph of a 2% agarose gel, in which the results of the fractionation of FIG. 2A-L were analyzed. The purified fraction collected in the elution chamber measured 344±20 base pairs (bp).

FIG. 3A is an illustration of a preparative electrophoresis cassette with an elution chamber.

FIG. 3B is an illustration of a preparative elution chamber from the perspective of the separation channel.

FIG. 3C is a pair of photographs of a preparative elution chamber. Left Panel: Exemplary dimensions for the elution chamber are as follows: diameter of sample collection port=2.5 mm, height of elution chamber=6 mm, width of elution chamber=8 mm, depth of elution chamber=6 mm. With respect to the opening in the side of the elution chamber, exemplary dimensions are as follows: the width=4 mm, height=3 mm. Right Panel: Disassembled view of elution chamber showing a first removable side, a sample collection chamber and a second removable side. The sample collection chamber contains a sample collection port, which is located, for instance, on the top side of the chamber.

FIG. 4A is a photograph of an electrophoresis cassette combined with the elution chamber of FIG. 3 and Example 2.

FIG. 4B is a photograph of an agarose gel analysis of fractions collected from the electrophoresis cassette of FIG. 4A.

FIG. 5A is an illustration of an electrophoresis cassette with a tapered separation channel combined with an elution chamber including a spacer, wedge, and O-ring seals. In one embodiment, the length of the separation channel from the distal edge of the sample well to the division point is 67 mm.

FIG. 5B is a series of illustrations of an elution chamber assembly shown in FIG. 5A. Exemplary dimensions of the elution chamber are as follows: the height of the sample collection chamber and the wedge=10 mm, the depth of the sample collection chamber=4 mm, and the diameter of the O-ring is 4 mm.

FIG. 6A-F is a series of photographs depicting the capture of a 200 bp fraction, of a DNA ladder over time using the electrophoresis cassette of FIG. 5 and Example 3. Arrow indicates the direction of electrophoresis at the division point.

FIG. 6G is a photograph of an agarose gel analysis of the experiment of FIG. 6A-F confirming the specific capture of the 200 bp fraction in the elution chamber.

FIG. 7 is an illustration of a multichannel preparative electrophoresis cassette.

FIG. 8A-H is a series of illustrations showing the fractionation of a sample over time using an exemplary detection system.

FIG. 9 is an illustration depicting the collection of a DNA fraction within an elution chamber having a DNA permeable membrane, a sample collection chamber for retaining DNA, and a DNA impermeable membrane, such as Nafion, to prevent DNA escape.

FIG. 10 is an illustration depicting the collection of a DNA fraction within an elution chamber having a gel plug, a buffer-filled sample collection chamber for retaining DNA, and a DNA impermeable membrane, such as Nafion, to prevent escape.

FIG. 11 is a schematic representation depicting an electrophoresis system with a T-shaped elution channel and a gel lens. This electrophoresis system contains an electrode chamber at the T-junction. Fractions are collected unilaterally.

FIG. 12 is a schematic representation depicting an electrophoresis system with a T-shaped elution channel without a gel lens. This electrophoresis system contains an electrode chamber at the T-junction. Fractions are collected unilaterally.

FIG. 13 is a schematic representation depicting an electrophoresis system with a T-shaped elution channel and a gel lens. This electrophoresis system contains an electrode chamber at the T-junction. Desired fractions are differentiated from the remaining sample by directing those fractions to the elution chamber (or selected-band elution well) rather than the waste reservoir (or waste elution well).

FIG. 14 is a schematic representation depicting an electrophoresis system with a T-shaped elution channel without a gel lens. This electrophoresis system contains an electrode chamber at the T-junction. Desired fractions are differentiated from the remaining sample by directing those fractions to the elution chamber (or selected-band elution well) rather than the waste reservoir (or waste elution well).

FIG. 15 is a schematic representation depicting an electrophoresis system with a T-shaped elution channel and a gel lens. This electrophoresis system is lacking an electrode module at the T-j unction depicted in FIGS. 11-14, and contains an optional electrode in its place. Desired fractions are differentiated from the remaining sample by directing those fractions to the elution chamber (or selected-band elution well) rather than the waste reservoir (or waste elution well).

FIG. 16 is a schematic representation depicting an electrophoresis system with a T-shaped elution channel without a gel lens. This electrophoresis system is lacking an electrode module at the T-junction depicted in FIGS. 11-14, and contains an optional electrode in its place. Desired fractions are differentiated from the remaining sample by directing those fractions to the elution chamber (or selected-band elution well) rather than the waste reservoir (or waste elution well).

FIG. 17 is a schematic representation depicting an electrophoresis system with asymmetric elution channels and a gel lens. Fractions are captured by using sample collection chambers having differentially permeable membranes on either end. Desired fractions are differentiated from the remaining sample by directing those fractions to elution Chamber A rather than elution Chamber B, or vice versa.

FIG. 18 is a schematic representation depicting an electrophoresis system with asymmetric elution channels and a gel lens. Fractions are captured by using sample collection chambers having differentially permeable membranes on either end. Desired fractions are differentiated from the remaining sample by directing those fractions to one or more designated elution chambers (e.g. Chamber A versus Chamber B or C). Although three elution chambers are depicted, the illustrated electrophoresis system can contain multiple channels of any number. Preferred embodiments contain up to 13 channels for sample or fraction collection.

FIG. 19 is series of schematics of a multichannel preparative electrophoresis cassette, having 5 macrofluidic channels. The channel plate is contacted to the cover plate and the sample well insert traverses the sample well insert opening of the cover plate. Three perspectives are shown.

FIG. 20 is a blow-up schematic of the multichannel preparative electrophoresis cassette of FIG. 19. The channel plate, elution chambers, cover plate, and sample well insert are detached to reveal detail.

FIG. 21 is a series of schematics of a multichannel preparative electrophoresis cassette, having 5 macrofluidic channels. Left Panel: The channel plate shows 5 tapered macrofluidic separation channels each having an elution chamber. Right Panel: The cover plate with a configuration of that corresponds to the channel plate.

FIG. 22 is a schematic of a multichannel preparative electrophoresis cassette, having 5 macrofluidic channels. The channel plate shows 5 tapered macrofluidic separation channels each having an elution chamber cavity for housing an elution chamber.

FIG. 23 is a schematic of the underside of the multichannel preparative electrophoresis cassette of FIG. 22.

FIG. 24 is a series of schematics of an elution chamber having a sample collection chamber and a sample collection port in two perspectives.

FIG. 25 is a series of schematics of an elution chamber having, with respect to the direction of electrophoresis, an analyte-permeable barrier, a sample-collection chamber, and an analyte-impermeable barrier. The sample collection chamber further contains a sample-collection port.

FIG. 26 is a series of schematics of an electrophoresis cassette contacted with a cover plate, wherein a buffer reservoir insert, a sample well insert, and a waste reservoir insert traverse the cover plate. Exemplary buffer reservoir inserts contain a vent. Furthermore, exemplary waste reservoir inserts contain at least one injection port. Three-perspectives are given of these components assembled and disassembled to show detail. Gels are caste by inserting a liquid gel matrix into the injection port and allowing the gel to harden into a solid form. Inserts are then removed and the resultant buffer reservoir, sample well, elution reservoir, and waste reservoir are filled with a buffer composition.

FIG. 27 is a schematic of an “uncovered” detection system, depicting an electophoresis cassette placed over light-emitting diodes and an optics housing, surrounded by the processor elements that signal detection and selective activation/deactivation of the electrode array.

FIG. 28 is a schematic of the “uncovered” detection system of FIG. 27 from an alternative perspective.

FIG. 29 is a schematic of the “covered” detection system of FIG. 27.

FIG. 30 is an illustration of the optical system of an exemplary electrophoresis system.

FIG. 31 is a graph of the fluorescence over time of mixed 50 and 100 by ladders detected using the system of FIG. 31, demonstrating the sensitivity of detection at a concentration of 1 ng per fraction, or band, within the separation channel.

FIG. 32 is a series of graphs depicting the fluorescence versus time signal of digested genomic DNA compared to a 100 bp DNA ladder. These graphs show the real-time optical detection to control DNA purification.

FIG. 33 is a schematic diagram of an exemplary basic electrophoresis system.

FIG. 34 is a schematic diagram of exemplary shapes of a constriction point within the separation channel of an electrophoresis cassette.

FIG. 35 is a schematic diagram of exemplary edge characteristics of a constriction point within the separation channel of an electrophoresis cassette.

FIG. 36 is a schematic diagram of an exemplary electrophoresis cassette base, without a cover, containing cavity for an upper dam (66) (a first dam), located distal to the buffer reservoir and proximal to the sample well cavity, and a cavity for a lower dam (67) (a second dam), located distal to the division point and proximal to the waste reservoir.

FIG. 37 is a schematic diagram of tilted view of the electrophoresis cassette shown in FIG. 36.

FIG. 38 is a schematic diagram of an exemplary electrophoresis cassette with a first dam, a second dam, and a solid gel, without a cover plate. The sample wells show a gel chimney.

FIG. 39 is a schematic diagram of an exemplary electrophoresis cassette cover, including at least one electrode port (68), at least one vent (49), at least one sample well port (69), at least one sample collection port of an elution chamber (29), and at least one injection or gel solution input port (50). The upper dam lies under the cover, positioned between the proximal electrode port and the vent hole. The lower dam lies under the cover, positioned between the gel solution input port and the distal electrode port.

FIG. 40 is a schematic diagram of a tilted view of the exemplary electrophoresis cassette and cover shown in FIG. 39.

FIG. 41 is a schematic diagram of an exemplary electrophoresis cassette including a first dam positioned within the cavity for the first dam and a second dam positioned within the cavity for the second dam.

FIG. 42 is a schematic diagram of an exemplary electrophoresis cassette, cross-sectioned in the center of the separation channel, to demonstrate the relative positions of the first and second dams, as well as the sample well insert and stripper plate.

FIG. 43A is a schematic diagram of a dam with a membrane attached to its plastic frame.

FIG. 43B is a schematic diagram of a dam depicted in FIG. 43A, in an exploded view.

FIG. 44 is a schematic diagram of an exemplary electrophoresis cassette, cross-sectioned in the vicinity of the sample well to depict the relative positions of the sample well insert and the stripper plate, which together, form a chimney-shaped sample well.

FIG. 45 is a schematic diagram of a rotated view of the electrophoresis cassette depicted in FIG. 44.

FIG. 46 is a schematic diagram of the rotated view of the electrophoresis cassette depicted in FIG. 45, with the sample well insert removed to show the resultant chimney sample well.

FIG. 47 is a schematic diagram of the rotated view of the electrophoresis cassette depicted in FIG. 46, with sample comb and the stripper plate removed to depict the chimney sample well ready for sample loading. Note that the top surface of the gel chimney is flush with the top of the cassette cover.

FIG. 48 is a photograph of an exemplary electrophoresis cassette similar to the one depicted in FIG. 47.

DETAILED DESCRIPTION

It is a common practice in biological experimentation to separate macromolecules such as proteins and nucleic acids, e.g., DNA or RNA, for analytical and preparative purposes using electrophoresis. Electrophoresis separates biomolecules by charge and/or size via mobility through a separating matrix in the presence of an electric field. Gel separating matrices are typically prepared from agarose for nucleic acid separation and polyacrylamide for protein separation. In capillary electrophoresis, the matrices may be gels or solutions (e.g., linear polyacrylamide solution).

Gel separating matrices are typically made by pouring a liquid phase material into a mold formed by glass plates or separating matrix casting molds. In slab gel electrophoresis, for example, finger shaped outcroppings in plastic material form “combs” that are embedded in the top of the separating matrix. Sample loading wells are formed when the combs are removed from the solidified separating matrix. Loading these wells is typically a time consuming and technically challenging task. Dense solutions such as glycerol or polyethylene glycol are often added to samples prior to electrophoresis to prevent samples from mixing with electrode buffers and floating out of the wells.

Samples, generally in an aqueous buffer, are applied to the separating matrix and electrodes in electrical contact with the separation matrix are used to apply an electric field. The field induces charged materials, such as nucleic acids and proteins, to migrate toward respective anode or cathode positions. Electrophoresis is usually completed in about 30 minutes to several hours.

The migration distances for the separated molecular species depend on their relative mobility through the separating matrix. Mobility of each species depends on hydrodynamic size and molecular charge. Proteins are often electrophoresed under conditions where each protein is complexed with a detergent or other material that imparts a negative charge to proteins in the sample. The detergent causes most or all of the proteins to migrate in the same direction (toward the electrophoresis anode). Samples are stained prior to, during, or after a separation run to visualize the nucleic acids or proteins within the gel. The location of the various components in the gel is determined using ultraviolet light absorbance, autoradiography, fluorescence, chemiluminescence, or any other well known means of detection. To determine the molecular weight and relative concentration of unknown nucleic acids or proteins, the band positions and intensities are typically compared to known molecular standards.

Electrophoresis cassettes and systems of the invention separate, condense, detect, analyze, and collect desired fractions of analytes within a biological sample. As described in the figures provided, and defined, in part, in Table 1, the cassettes and systems of the invention includes distinctive features and corresponding functions.

Exemplary electrophoresis cassettes are molded from a plastic, such as polystyrene and its derivatives, or PMMA. Alternatively, the electrophoresis cassette is molded using any optically clear polymer. Electrophoresis cassettes are either molded as one contiguous piece, or they are assembled from multiple pieces, each molded from plastic or an appropriate optically clear plastic that are connected to form a contiguous piece.

Electrophoresis cassettes of the invention include macrofluidic channels, rather than microfluidic channels or nanochannels, to direct and fraction samples. The use of macrofluidic channels is essential to ensure that a sufficient amount of an analyte or sample is prepared or analyzed within a single application of the sample to the cassette such that the collected fraction can be used directly for further manipulation and analysis. For example, an isolated analyte or fraction is subsequently sequenced or inserted into a vector or cell.

Macrofluidic channels of the invention have a minimal demonstrated width of 2 mm, which occurs at either the constriction point or division point of the channel (FIG. 1C). The greatest demonstrated width of the macrofluidic channels of the invention is 7 mm (FIG. 1C), which occurs near the sample well cavity of the separation channel. In most embodiments the depth of the macrofluidic channel is uniform, at approximately 6 mm (FIG. 1C). However, these dimensions increase and decrease within preferred ranges. The preferred width of a macrofluidic channel ranges from between 2 mm to 10 mm and the preferred depth of a macrofluidic channel ranges from between 2 mm to 10 mm.

Macrofluidic channels of the invention include physically and electrically isolated portions. The term “physically isolated” is meant to describe a channel arrangement in which one portion of the channel is separated from another portion of the channel by a physical barrier such that the analyte contained in one portion cannot intermix with the analyte contained in another portion. The term “electrically isolated” is meant to describe a channel arrangement in which the electrode positioned at one portion of the channel is controlled separately from the electrode positioned at another portion of the channel. The use of electrically and physically isolated channels both prevents contamination of the selected fractions, which can occur in gel slab systems that lack any barriers between lanes, and improves directional elution of selected fragments.

Macrofluidic channels also contain cavities and reservoirs. The term “cavity” is used to describe a portion of the channel that is reserved for either the attachment of a structure, the insertion of a structure within its volume, of the generation of a structure. A structure is formed, for instance by the placement of the sample well insert into the sample well cavity, the injection and solidification of a gel matrix composition, and the removal of the sample well insert. The term “reservoir” is meant to describe a cavity that is filled with a buffer composition.

Elution chambers of the invention include analyte-permeable and analyte-impermeable barriers. The term “analyte-permeable” is meant to describe any barrier that is permeable to ions, polynucleic acids, and polypeptides, but not to, any other component of the gel matrix composition or buffer composition. The term “analyte-impermeable” is meant to describe any barrier that is permeable to ions, but impermeable to polynucleic acids, polypeptides, any other component of the gel matrix composition, buffer composition, or elution composition.

One of the superior properties of the electrophoresis cassette of the invention is the collection analyte, or fraction thereof, in an elution buffer composition. Other preparative electrophoresis systems require the user to extract, for example, a DNA fraction, from a gel or membrane following electrophoresis. This secondary DNA extraction step is time-consuming and significantly decreases the overall yield of DNA obtained from that fraction. In contrast, electrophoresis systems of the invention integrate the steps of polynucleotide or polypeptide separation and collection by providing an elution chamber, which simultaneously fractions and extracts the polynucleotide or polypeptide analyte into any desired elution buffer.

Macrofluidic channels also include one or more engineered constriction points. Constriction points enable and improve the isolation of an analyte within sample. Physical parameters of the constriction point vary among exemplary electrophoresis cassettes and separation channels. Constriction points within existing preparative electrophoresis systems have been used to hold a vertical gel in place and reduce the volume of eluting liquid before capture. In contrast, the physical constriction of the separation channel within the electrophoresis cassettes of the invention produces an electric field gradient. In a basic embodiment, a small bore hole drilled in a plastic block serves as a constriction point.

Features of the constriction, or constriction point, vary between electrophoresis cassettes and between separation channels of a multichannel cassette. For example, the shape of the constriction by cross-sectional view is either a venturi tube, flow nozzle, or orifice place, as shown in FIG. 34. The placement of the constriction point within the separation channel varies. When the electrophoresis cassette is divided in half horizontally, through the separation channel, the constriction point is positioned either within the top or bottom half of the channel. When the electrophoresis cassette is divided in half vertically, through the separation channel, the constriction point is positioned either within the left or right half of the channel. Alternatively, the constriction point is located in the center of the separation channel, considered from either above-referenced perspective. From a perspective directly facing the constriction point, or a head-on perspective, the shape of the constriction is circular, oval, square, or rectangular. The cross-sectional area occupied by the constriction in comparison with the cross-sectional area of the separation channel, either upstream or downstream of the division or branch point varies. In certain embodiments the cross-sectional area occupied by the constriction occupies 90%, 80%, 70%, 60%, 50%, 40%, 30%, 20%, 10%, 5%, or any percentage point in between of the cross-sectional area of the separation channel. Additional parameters that vary between separation channels of a multichannel electrophoresis cassette or between electrophoresis cassettes include, but are not limited to, the length of the constriction, the gradient of the taper and/or flare of the constriction, the symmetry or asymmetry of the constriction, and the material used to form the constriction, as well as the texture/uniformity of that material.

The constriction point of the macrofluidic separation channel can also be the division point. Alternatively, the macrofluidic separation channel contains at least one division point. The term “division point” is meant to describe a point at which the macrofluidic channel splits or branches into one or more physically and electrically isolated portions.

Macrofluidic channels contain at least one of a gel matrix composition, a liquid buffer composition, or a solid buffer composition. Gel matrix compositions contain a polymerizing compound, such as agarose or polyacrylamide, for the separation of polynucleic acids and polypeptides, respectively. Polymerizing compounds are provided at percentages ranging from 0.01%-99.9%. Electrophoresis buffer compositions known in art are used herein. Buffer solutions are preferably electrolyte solutions.

Electrophoresis cassettes optionally contain electrodes that are either disposable or reusable. Disposable electrodes are integrated into the cassettes and made from epoxy with conductive particles, inks, or rubber. Reusable electrodes are made of coated titanium or platinum probes.

Sample wells have multiple geometries. The geometry of the sample well reflects the geometry of the sample well insert used to define the negative space not occupied by the gel matrix composition. Preferably, the sample wells of the invention have the have a unique and essential “chimney” shape depicted in FIGS. 44-48. Generally, sample well insert, or sample comb has a simple rectangular shape, which forms a simple rectangular negative space within the gel. As such, in such a gel, the top of the sample well is level with the top of the gel and, if a cover were applied, the top of the well would be flush or level with the bottom of the cover. However, under certain circumstances this sample well geometry, particularly when a cover is attached to the electrophoresis cassette base, allows for leakage of the sample in the liquid-filled space between the top of the gel and the cover plate. This leakage leads to contamination of the desired fractions within the eluction chamber.

The chimney geometry was developed in conjunction with an adaptation of the cover, i.e. the sample well port, to support the gel chimney and prevent leakage of the sample, and, therefore, contamination of desired fractions within the elution chamber. The sample well port of the cover is adapted to support the gel chimneys of the sample well.

The chimney well is a superior property of this invention because the purpose of preparative electrophoresis is the precise and exact separation of fractions from a sample that differs in a physical property. In certain circumstances, the differences between collected and discarded fractions are very subtle. Contamination of the collected fractions with random analyte from the sample pulled into the seam by capillary action between the gel and the bottom of the cover plate significantly distorts the results. Thus, the prevention of this contamination and the creation of chimney wells provides a superior and distinguishing feature of the invention.

Samples, Analytes, and Fractions

Electrophoresis cassettes and detection systems of the invention fractionate, analyze, and collect polynucleic acid and polypeptide analytes or fractions within a sample.

The term “sample” describes a plurality of molecules that can be separated using gel electrophoresis. The term “fraction” describes a subset of the plurality of molecules within a sample. A fraction is defined or determined by size. Alternatively, a fraction is defined or determined by any physical property that causes it to migrate at a faster or slower rate than other components or fractions of a sample when driven to migrate through a buffer composition of the invention by the force of an electric field (i.e., electrophoretic mobility).

An exemplary sample includes, but is not limited to, a nucleic acid, an oligonucleotide, a DNA molecule, a RNA molecule, or any combination thereof. Alternatively, or in addition, a sample includes, but is not limited to, an amino acid, a peptide, a protein, or any combination thereof. For example, a sample is a whole cell lysate, or the DNA or protein fraction of a cell lysate.

Nucleic acids are derived from genomic DNA, double-stranded DNA (dsDNA), single-stranded DNA (ssDNA), coding DNA (or cDNA), messenger RNA (mRNA), short interfering RNA (SiRNA), short-hairpin RNA (shRNA), microRNA (miRNA), single-stranded RNA, double-stranded RNA (dsRNA), a morpholino, RNA interference (RNAi) molecule, mitochondrial nucleic acid, chloroplast nucleic acid, viral DNA, viral RNA, and other organelles with separate genetic material. Furthermore, samples include nucleic acid analogs that contain modified, synthetic, or non-naturally occurring nucleotides or structural elements or other alternative/modified nucleic acid chemistries known in the art. Additional examples of nucleic acid modifications include the use of base analogs such as inosine, intercalators (U.S. Pat. No. 4,835,263) and minor groove binders (U.S. Pat. No. 5,801,115). Other examples of nucleic acid analogs and alternative/modified nucleic acid chemistries known in the art are described in Current Protocols in Nucleic Acid Chemistry, John Wiley & Sons, N.Y. (2002).

PNA oligomers are included in exemplary samples or fractions of the invention. PNA oligomers are analogs of DNA in which the phosphate backbone is replaced with a peptide-like backbone (Lagriffoul et al., Bioorganic & Medicinal Chemistry Letters, 4: 1081-1082 (1994), Petersen et al., Bioorganic & Medicinal Chemistry Letters, 6: 793-796 (1996), Kumar et al., Organic Letters 3(9): 1269-1272 (2001), WO96/04000).

Polypeptides or proteins are complex, three-dimensional structures containing one or more long, folded polypeptide chains. Polypeptide chains are composed of a plurality of small chemical units called amino acids. Naturally occurring amino acids have an L-configuration. Synthetic peptides can be prepared employing conventional synthetic methods, using L-amino acids, D-amino acids or various combinations of L- and D-amino acids. The term “peptide” describes a combination two or more amino acids. Naturally occurring amino acids have an L-configuration. Peptides having fewer than ten amino acids are “oligopeptides,” whereas peptides containing a greater number of amino acid units are “polypeptides.” Any reference to a “polypeptide” also includes an oligopeptide. Further, any reference to a “peptide” includes polypeptides and oligopeptides. Each different arrangement of amino acids forms a different polypeptide chain.

The term “nucleic acid molecule” describes the phosphate ester polymeric form of ribonucleosides (adenosine, guanosine, uridine or cytidine; “RNA molecules”) or deoxyribonucleosides (deoxyadenosine, deoxyguanosine, deoxythymidine, or deoxycytidine; “DNA molecules”), or any phosphoester analogues thereof, such as phosphorothioates and thioesters, in either single stranded form, or a double-stranded helix. The term nucleic acid molecule, and in particular DNA or RNA molecule, refers only to the primary and secondary structure of the molecule, and does not limit it to any particular tertiary forms. Thus, this term includes double-stranded DNA found, in linear or circular DNA molecules (e.g., restriction fragments), plasmids, and chromosomes. A “recombinant DNA molecule” is a DNA molecule that has undergone a molecular biological manipulation. (see Sambrook et al. Molecular Cloning, A Laboratory Manual, Cold Spring Harbor Laboratory Press).

Samples are combined with a reagent that imparts a net negative charge, denatures a peptide or protein, or digests a DNA or RNA molecule prior to application to an electrophoresis system. These reagents are known in the art. Furthermore, samples are combined with agents that impart fluorescent, magnetic, or radioactive properties to the sample or fractions thereof for the purpose of detection. In one embodiment of the system, a dsDNA sample is mixed with ethidium bromide, applied to the electrophoresis cassette, and fractions of the sample are detected using an ultrabright green LED.

All standard and specialty buffers known in the art are used with samples, and fractions thereof, as well as to make the buffer compositions the fill the electrophoresis cassettes of the system.

Regarding polypeptides, the term “native” is meant to describe a non-denatured polypeptide. Polypeptide analytes of the invention are native or denatured.

Detection System

Detection systems of the invention are compact and automated. These systems are designed and intended for desktop or bench-top use. Furthermore, electrophoresis cassettes of these systems are disposable.

Systems include at least one electrophoresis cassette with means to fractionate, detect, analyze, and collect a polynucleic acid or polypeptide analyte or fraction within a sample.

Systems also include a detection module with means to detect and analyze, for instance, to quantify, a signal. Exemplary signals include, but are not limited to, visible light, fluorescent light, magnetic fields, and radioactivity. Detection modules are positioned at a detection zone or constriction point of the separation channel of an electrophoresis cassette. Alternatively, the position of the detection module is shifted towards the entry or exit points of the constriction. The constriction point or detection zone is proximal to the sample well. The detector tracks a marker and the processor determines, based upon the size, speed, electrophoretic mobility, and/or timing of the marker, when an analyte of the desired molecular weight or electrophoretic mobility will traverse the division point.

Included in these systems is an illumination source that is either independently incorporated into the system or incorporated into the detection module. The illumination source uses ultra bright light emitting diode (LED) in combination with a filter set and one or more photodiodes, for instance.

The detection module of the system, which optionally includes an illumination source, is coupled with a microprocessor control system. The microprocessor control system includes a microprocessor, software, and a set of relays with means to control a voltage switching scheme that differentially activates a combination of the negative and at least one positive electrode in order to divert a sample or fraction thereof to an intended collection point at the end of the separation channel. In another aspect of the invention, a laptop is substituted for the use of an incorporated microprocessor. Exemplary software for controlling these systems is developed for use on a laptop or with the incorporated microprocessor.

Systems further include an integrated or separate power source.

Systems of the invention are designed to such that the separation channels of the incorporated electrophoresis cassettes are positioned horizontally with respect to a table- or desktop. Alternatively, the system is configured such that the separation channels of the incorporated electrophoresis cassettes are positioned vertically with respect to a table- or desktop.

TABLE 1 Figure Reference Numbers Reference Number Structure 1 Base plate 2 Channel plate 3 Waste reservoir 4 Elution reservoir 5 First physically and electrically isolated portion of separation channel 6 Second physically and electrically isolated portion of separation channel 7 Division Point 8 Constriction Point 9 Separation channel 10 Sample well cavity 11 Buffer reservoir 12 Alignment excision 13 Elution reservoir insert opening 14 Waste reservoir insert opening 15 Constriction and division point opening 16 Sample well insert opening 17 Buffer reservoir insert opening 18 Buffer reservoir insert 19 Sample well insert 20 Elution reservoir insert 21 Waste reservoir insert 22 End of separation channel 23 Cover plate 24 DNA sample 25 Desired analyte or fraction 26 Groove 27 First removable end of elution chamber 28 Sample collection chamber of elution chamber 29 Sample collection port of elution chamber 30 Second removable end of elution chamber 31 Gasket 32 Analyte-permeable barrier (e.g. Durapore Membrane) 33 Analyte-impermeable barrier (e.g. Nafion Membrane) 34 Elution chamber spacer 35 Elution chamber wedge 36 Sample collection channel 37 O-ring 38 DNA Marker 39 Negative Electrode 40 Sample well 41 Positive Electrode 42 Connector 43 Elution chamber opening in cover 44 Alignment protrusion 45 Elution chamber cavity 46 Elution chamber 47 Elution reservoir and waste reservoir cavity 48 Waste reservoir insert 49 Vent 50 Injection Port 51 Electrophoresis cassette 52 Processor board for power module 53 Input/Output connector 54 Single computer board 55 Optics housing 56 Photodetector 57 Photodetector processor board 58 Hard disk drive 59 Light-emitting diode 60 Casing of detector system 61 Light-emitting diode 62 Emission filter 63 Light-focusing filter 64 Dichronic mirror 65 Excitation filter 66 Cavity for upper dam (first dam) 67 Cavity for lower dam (second dam) 68 Electrode Port 69 Sample Well Port 70 Dam Frame 71 Dam Membrane 72 Gel Chimney 73 Cover Alignment Pins 74 Negative (−) Electrode Port 75 Positive (+) Electrode Port 76 Upper/First Dam 77 Lower/Second Dam 78 Top of Gel 79 Gel 80 Stripper Plate

EXAMPLES Example 1 Size Fractionation of Genomic DNA by Agarose Gel Electrophoresis in Y-Shaped Cassette

The Y-shaped cassette used for this experiment is illustrated in FIG. 1. The channel plate and cover were machined from polycarbonate, the base was fused silica, and the molding inserts used to form buffer and sample wells were machined from Teflon. To cast the gel cassette, the channel plate was coated front and back with a thin coating of a dielectric silicone sealant to prevent leakage of buffer and electrical current. The base and cover were pressed against the channel plate and held together with binder clips throughout casting and electrophoresis.

The electrophoresis gel used was 2% agarose (SeaKem LE agarose, Lonza) in 0.5×KBB buffer (1×KBB buffer is 12.4 g/liter Tris base, 14 g/liter TAPS acid, 0.048 g/liter EDTA free acid). The gel and liquid buffer contained 1.5 ug/ml ethidium bromide, to enable visualization of the DNA by fluorescence under UV transillumination. The agarose was heated in water until dissolved and then cooled to approximately 60° C. Buffer and ethidium were added and the solution was thoroughly mixed. The cassette was filled in a horizontal position, with all well-forming inserts removed, until the cassette was slightly overfilled. The well-forming inserts were immediately installed. The triangular gap in the cassette cover which is located over the channel constriction was covered with a glass coverslip. Care was taken to avoid introduction of bubbles or silicone sealant into the channel.

The cassette was allowed to solidify for approximately 1 hour at room temperature. The well-forming inserts were removed from the cassette and all wells were filled with electrophoresis buffer (0.5×KBB buffer with 1.5 ug/ml ethidium bromide). The cassette was placed in a horizontal position on a UV transilluminator (Fotodyne, 300 nm peak output). A high voltage electrophoresis power supply (E-C apparatus) was connected to platinum electrodes in the buffer reservoirs of the cassette.

A sample of calf thymus DNA (Sigma Chemical) was digested to completion with BfuCI (New England Biolabs). Two ug of digested DNA was dissolved in 40 ul of 40% sucrose, 10 mM Tris-HCl, pH 8.0, 1 mM EDTA, and loaded in the sample well of the cassette.

Electrophoresis was carried out at a constant voltage of 100 V. The negative electrode was connected to the single buffer reservoir upstream from the sample well. The positive electrode was connected to buffer reservoir of the waste leg of the cassette initially. The electrophoresis buffer reservoirs were exchanged with fresh buffer every 10 minutes during the run.

Electrophoresis was carried out using the waste leg electrode for 57 minutes (see images FIG. 2A-C). At that point, waste leg electrode was disconnected, and the purification leg electrode was connected to the power supply for 2 minutes (see images FIGS. 2D-G). After 2 minutes, the purification leg electrode was disconnected and the waste leg electrode was reconnected. Electrophoresis was continued into the waste leg for approximately 3-4 more minutes (see images FIGS. 2H-L). Then power was turned off. The cassette was unclamped and the cover was removed. The gel in the separation channel was cut away from the gel in the purification and waste legs of the cassette near the narrowest point of the legs. The separation channel gel was discarded and the separation channel was refilled with electrophoresis buffer.

DNA in the waste and purification channels was isolated by electrophoresing the DNA onto strips of DEAE ion-exchange membrane (Sartorius Stedim) were inserted into thin horizontal slits in the gel just downstream of the desired DNA fractions (see FIG. 2L). Electrophoretic capture of the DNA on the membranes was carried out at 100 V for approximately seven minutes. Purification leg DNA was isolated first and sample membrane was removed to prior to isolation of DNA from the waste leg.

DNA was recovered from ion-exchange membranes, by immersing membranes in 0.4 ml 1×KBB and 1M NaCl at 65° C. for 30 minutes. After removal of ion-exchange strips from tubes, 10 ul of 0.25% linear polyacrylamide was added to each tube and vortexed to mix. DNA was precipitated with 1 ml ethanol to each tube. DNA pellets were rinsed in 100% ethanol, and air dried. DNA samples were resuspended in 15 ul TE buffer (10 mM Tris-HCl, pH 8.0, 1 mM EDTA), and mixed with 15 ul of 40% sucrose in TE buffer. Entire amount was loaded onto 2% analytical slab agarose gel in 0.5×KBB with 1.5 ug/ml ethidium bromide. The image of the analytical gel is shown in FIG. 2M. The DNA recovered from the purification leg measures approximately 344 bp with an edge to edge band width of approximately 40 bp. The DNA from the waste leg shows almost complete absence of DNA in the region of 340 bp, indicating good purification efficiency into the purification leg.

Example 2 Size Fractionation of Genomic DNA by Agarose Gel Electrophoresis in Y-Shaped Cassette with Liquid Filled Elution Chamber

In order to demonstrate recovery of fractionated size-selected DNA in a liquid filled buffer chamber, the device of FIG. 1 was modified to include a membrane-bounded chamber in the purification channel. The cassette with elution chamber is shown in FIGS. 3A-C. The dimensions of the separation channel and waste channel were similar to the cassette of FIG. 1.

The elution chamber was a rectangular plastic channel (polycarbonate) that was bounded on the front side (the side proximal to the separation channel, see FIG. 4A, 3B) by a membrane that is porous to DNA, and low in nonspecific DNA binding (Durapore SVLP, Millipore, 5 um pore size). On the back side of the chamber (the side proximal to the (+) electrode, see FIG. 4A, 3B), a membrane that is non-porous to DNA and low in nonspecific DNA binding was installed (Nafion 117, Ion Power). The membranes were tightly sealed over the faces of the elution chamber by rectangular plastic frames that snap over the protruding lip of the chamber (see FIG. 3C). The top surface of the elution chamber has a small circular hole which was used for filling and emptying the channel with a standard handheld micropipettor (FIGS. 3C and 4A). The volume of the fully assembled elution chamber was approximately 90 ul.

The cassette was assembled as described in Example 1, with the exceptions that dielectric silicone sealant was not used between the channel plate and the top cover. In this example, the top surface of the channel plate was sealed with a cast silicone gasket, which is labeled in FIGS. 3C and 4A.

The agarose gel (same composition as in Example 1) was cast with an empty, membrane-free elution chamber inserted into the cassette. After the gel solidified, the top plate was removed and the gel column was sliced across the front and back openings of the gel elution chamber. The elution module was removed and the gel was cleaned from the inside of the module. Nafion and Durapore membranes were assembled onto the chamber, and it was reinserted into the cassette. Dielectric silicone sealant was used on the side and bottom exterior surfaces of the elution chamber to prevent electrical leaks around the elution chamber. The assembled cassette was clamped with binder clips as in Example 1.

The sample was 2 ug BfuCI-digested calf thymus genomic DNA. Electrophoresis was carried out at constant voltage of 100 V. The waste channel electrode was used for 1 hr and 9 minutes, and then voltage was switched to the purification channel for 5 minutes. Following this, voltage was switched back to the waste channel for an additional 3 minutes before terminating electrophoresis.

After the run, 90 ul of buffer was removed from the elution chamber with a handheld micropipette. Eluted sample was ethanol precipitated as described in example 1. To estimate the efficiency of DNA recovery by the process, DNA in the gel of the waste leg was isolated in the vicinity of the “gap” in the DNA pattern (caused by the removal of DNA into the purification channel). DNA was extracted from the gel slice using a commercial kit (Qiagen Minelute Gel extraction kit).

An analytical 2% agarose gel of the products (see FIG. 4B) shows efficient purification of a DNA band of approximately 300 bp, similar to the results shown in Example 1. In this example, however, the selected DNA product was obtained in liquid buffer directly from the elution chamber, without the need to perform gel extraction. The fractionation process was efficient, as judged by the absence of similar-sized DNA in the sample recovered from the waste channel.

Example 3 Purification of Specific DNA Band in Cassette with Tapered Channel and Simplified Elution Chamber Design

An alternative cassetted design is shown in FIGS. 5A-B. The cassette features a tapered separation channel. As seen in FIGS. 6D-F, DNA bands are compacted from their original thin and wide shape near the sample well into square (or compact rectangular) shapes as they arrive at the three-way channel junction. For this reason, a tapered separation channel should provide improved size resolution in purification when compared with separation channels with rectangular profile like those described in Examples 1 and 2 above.

The elution chamber of this cassette is constructed from three plastic parts shown in FIG. 5B. Compressible O-rings are used to position and seal membranes on either side of the elution chamber, as illustrated in FIG. 5B. The volume of the elution chamber is approximately 50 ul.

To cast the gel used for this example (same gel and buffer formulation as used in Example 1 above), the top and bottom surface of the channel plate was sealed with clear packaging tape (Scotch brand packaging tape, 3M). The purification channel and electrophoresis buffer compartments were left uncovered on the top side of the channel plate. The elution chamber was assembled with a non-porous sheet of PETG sealing the chamber entrance from the separation channel side. The gel was cast through the buffer reservoir of the waste channel, thereby filling the waste and separation channels only. The purification channel contained no gel, except at the entrance to the elution chamber. After the gel solidified, the elution chamber was disassembled and the PETG membrane was discarded. The purification channel was filled with electrophoresis buffer. The elution chamber was reassembled in the buffer-filled purification channel with porous membrane (Durapore BVPP, 1 um pore size, Millipore) on the separation channel side of the chamber, and non-porous membrane (Nafion 117) on the electrode side of the chamber. Care was taken to ensure that no bubbles were trapped in the channel through the elution chamber and spacer.

The sample consisted of 1 ug of a 100 bp DNA marker ladder (100 bp ladder, New England Biolabs). Electrophoresis was carried out a constant voltage of 100 V. The waste channel electrode was used (see FIGS. 6A-D) until the 200 bp marker arrived at the three way junction between separation, purification, and waste channels (approximately 71 minutes into the run, see FIG. 6E). At this point, voltage was switched to the purification channel and the 200 bp band was driven into the elution chamber for 6 minutes (see FIGS. 6E-F). The voltage was switched back to the waste channel for an additional 15 minutes after which the run was terminated.

The purified sample (50 ul) was withdrawn from the elution chamber with a handheld micropipette DNA from the gel of the waste channel was extracted using a commercial kit (Qiagen QlAquick Gel Extraction kit) and eluted in 50 ul of 10 mM Tris-HCl buffer. Input DNA (1 ug of 100 bp DNA ladder, NEB) was diluted to 50 ul in TE buffer. All three samples were mixed with 10 ul of 40% sucrose in TE buffer containing a small amount of bromophenol blue loading dye and loaded on a 5% acrylamide gel (29:1, mon:bis, 0.5×KBB buffer) for analysis. The image of the ethidium-stained gel is shown in FIG. 6G. There is some distortion of the bands due to the extremely large sample volume (60 ul for all samples), and differences in salt: waste channel DNA and input ladder DNA was dissolved in 10 mM Tris-HCl, whereas purified DNA was loaded in electrophoresis buffer from elution chamber. However, the results show that the targeted 200 bp band was efficiently removed from the input sample (see absence of 200 bp band in waste channel DNA) and efficiently recovered from the elution chamber.

Example 4 Multichannel Cassettes for Automated Preparative Electrophoresis

In some embodiments of the invention, multichannel cassettes are used. Exemplary multichannel cassettes are shown in FIGS. 7, 19, 20, 21, 22, 23, 26, 28, 29, 30, and 31. Multichannel cassettes rapidly process multiple samples. Moreover, multichannel cassettes provide a means by which the molecular weight of an uncharacterized sample in a first macrofluidic channel of the cassette can be estimated by comparison with molecular weight markers run in a second macrofluidic channel of the same cassette.

Example 5 Vertical Casting of Multichannel Cassettes

The macrofluidic separation channel, including the first and second physically and electrically separated ends, to the proximal sides of the elution chamber (up to the face of the permeable membrane) and the waste reservoir, respectively, are filled with agarose gel. To cast the gel, in accordance with FIG. 26, the channel plate is contacted with the cover plate, and a waste reservoir insert is inserted into the corresponding opening in the cover plate, a sample well insert is inserted into the corresponding opening in the cover, and a buffer reservoir insert is inserted into the corresponding opening in the cover plate. The buffer insert contains a vent and the waste insert contains an injection port. The inserts are designed to seal tightly against the cover plate to prevent leakage of the molten agarose solution. Molten agarose is injected into each channel through ports that extend through the waste reservoir insert and open into the bottom end of the second physically and electrically isolated portion of the separation channel. Molten agarose mixture is injected from syringes or automated liquid dispensing instruments through the injection port into the second physically and electrically isolated portion of the separation channel. During casting of the gel, the cassette is held in a vertical position (proximal end up), thereby filling the separation channel and the proximal regions of the first and second physically and electrically isolated portions from the bottom up. In the first physically and electrically isolated portion of the separation channel, the molten gel fills the space extending from the division point to the proximal side of the elution chamber. Care is maintained to avoid trapping air bubbles at any point. The injection and vent ports completely occupy the volume of the waste and buffer reservoirs, thereby precisely determining the boundaries of the gel column on either end, where the gel meets the ports.

Example 6 Horizontal Casting of Multichannel Cassettes

The macrofluidic separation channel, including the first and second physically and electrically separated ends, to the proximal sides of the elution chamber (up to the face of the permeable membrane) and the waste reservoir, respectively, are filled with agarose gel. To cast the gel, in accordance with FIGS. 36 and 37, the first and second dams are inserted into the electrophoresis base plate, which, subsequently, is contacted with the cover plate (as shown in FIG. 39). A sample well insert is inserted into the sample well port. The sample well port contains a raised edge around the opening in the cover plate through which the samples well insert(s) traverses. With the aid of the stripper plate, the teeth of the sample well insert are held centrally within the opening in the cover place such that a space is preserved on all sides of the teeth and the resultant sample well containing a deep central portion with high walls (FIG. 44), however, the walls or “gel chimneys” do not extend past the bottom of the stripper plate. Molten agarose is injected into the injection port of the cover corresponding to each channel. The sample port is located proximal to the second dam. Molten agarose mixture is injected from syringes, pipettes, or automated liquid dispensing instruments through the injection port. During casting of the gel, the cassette maintained in a horizontal position, thereby allowing the molten agarose to spread through the separation channel until it reaches the first dam at the proximal end of the sample well cavity, in which the sample well insert resides. Air is permitted to escape through the vents in the cover while the molten agarose is being inserted (FIG. 39). At the completion of the casting process, the cover is removed and the buffer reservoir, elution chamber, elution reservoir, and waste reservoirs are filled with a buffer composition. The elution chamber is filled with an elution buffer. The portion of the separation channel extending from the sample well cavity through the proximal side of the elution chamber and the proximal side of the waste reservoir is filled with solid agarose. The cover is replaced and the cassette is sealed.

OTHER EMBODIMENTS

While the invention has been described in conjunction with the detailed description thereof, the foregoing description is intended to illustrate and not limit the scope of the invention, which is defined by the scope of the appended claims. Other aspects, advantages, and modifications are within the scope of the following claims.

The patent and scientific literature referred to herein establishes the knowledge that is available to those with skill in the art. All United States patents and published or unpublished United States patent applications cited herein are incorporated by reference. All published foreign patents and patent applications cited herein are hereby incorporated by reference. All other published references, documents, manuscripts and scientific literature cited herein are hereby incorporated by reference.

While this invention has been particularly shown and described with references to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the invention encompassed by the appended claims. 

1-85. (canceled)
 86. An electrophoresis cassette comprising: a plate including at least one microfluidic separation channel, the channel having a first portion and a second portion; and an elution chamber comprising at least one of an elution cavity and a barrier. 